JPS6330880Y2 - - Google Patents

Description

[Detailed description of the invention] <Industrial application field> The present invention is applicable to liquefied carbon gas cylinders used as shielding gas during welding, and liquefied laughing gas cylinders used for medical purposes. The present invention relates to a gas pressure regulating device capable of predicting gas out-of-gas conditions.

《Prior art》 Conventionally, when welding, for example, the first
As shown in the figure, a liquefied carbon dioxide gas cylinder A is prepared, and a gas pressure regulator B and a gas flowmeter C are connected to its main valve in sequence, and the outlet side of the flowmeter C is connected to a welding power supply D, and the gas cylinder A CO ₂ supplied from the wire feeder E is supplied to the torch F, and the torch F and base material G
It is known to apply a DC voltage between the two and use CO ₂ as a shielding gas in this way.

However, as mentioned above, as a gas pressure regulating device, the gas pressure regulator B can supply a predetermined pressure-reducing gas, and the flow rate regulating valve C' can supply a gas flow meter C.
Since it is simply a device that allows the supply gas flow rate to be adjusted while looking at the scale, liquefied carbon dioxide gas cylinder A may run out of gas during welding work, and as a result, workers are constantly running out of gas. Not only does this require anxiety, but there is also the drawback that replacing cylinder A during the work may result in uneven welding.

Therefore, a device has been proposed that detects the gas shortage in the cylinder A, reports it, and issues an alarm.However, this type of device measures the internal pressure of the cylinder and calculates a pressure of, for example, 1 to 1.2 kg/cm. An alarm is issued when the gas pressure drops to ² G.

By the way, the cylinder internal pressure P of the liquefied carbon gas cylinder A
The relationship between the amount of gas used and the amount of gas used in the same cylinder W is as shown in Figure 2. Even when the cylinder is used, the internal pressure does not drop in proportion to this, and when the internal pressure P of the cylinder decreases, the liquid inside the cylinder decreases. is close to zero, and therefore, the alarm only lets you know that the gas is running out, and it is not possible to know in advance that the gas is running out and take countermeasures such as replacing the cylinder with a new one.

[Problems to be solved by the invention] In view of the above-mentioned difficulties of the conventional device, the present invention not only displays the instantaneous flow rate of gas using a conventional gas flow meter, but also displays the cumulative flow rate of gas on the meter. The system is equipped with a function to measure the amount of gas remaining in the gas cylinder, and from the relationship between this measurement result and the amount of full gas in the gas cylinder, which can be known in advance, the remaining amount of gas in the gas cylinder can be accurately predicted and an alarm can be issued. The purpose is to eliminate the aforementioned deficiencies of the prior art.

<Means for Solving the Problems> In order to achieve the above object, the present invention connects the primary side of a gas pressure regulator having a pressure adjustment knob and a secondary side pressure gauge to the main valve of a liquefied gas cylinder, A gas inlet of a gas flow meter having a gas outlet is connected to the secondary side of the regulator via a gas flow rate adjustment valve, and the gas flow meter has an instantaneous flow rate of gas and an integrated gas flow rate. An electric circuit for measuring the instantaneous and cumulative flow rate is equipped with an indicator that indicates the flow rate or the remaining amount of gas in the cylinder, and the display indicates that the cumulative flow rate of the gas concerned or the remaining amount of gas in the cylinder has reached the set value. A liquefied gas cylinder pressure regulator connected to an activated alarm.

<Operation> Not only can the instantaneous flow rate of gas be measured by the display part of the electric circuit for measuring instantaneous and cumulative flow rate, but also the display part can display the cumulative gas flow rate or the current flow rate and the full amount of gas in the gas cylinder. Since the remaining amount of gas in the cylinder is displayed, which is known from the difference between It is possible to warn when this has been reached, and it is possible to have higher reliability than the conventional prediction of the remaining amount based on the internal pressure of the gas cylinder.

《Example》 Figure 3 shows an example in the case of welding as in Figure 1, in which the device of the present invention is connected to a welding power source D, and as is known, the main valve 1' of the liquefied gas cylinder 1 and the gas pressure regulator are connected. The primary side of 2 is connected by a pipe 3, and the secondary side of the synchronized pressure device 2 and the gas inlet 5 of the gas flow meter 4 are connected by a pipe 3' via a gas flow rate adjustment valve 6. The gas passes from the gas inlet 5 to the gas flow meter 4 through an internal gas passage, and flows out from the gas outlet 7. In the illustrated case, the gas is introduced into the welding power supply device D by a pipe 3''.

In the figure, reference numeral 8 indicates a secondary side pressure gauge of the gas pressure regulator 2 as is also known, 9 indicates a pressure adjustment knob of the regulator 2, and a gas flow meter 4 is connected from the welding power source D. power is provided to the
Electric current from the device D can also be supplied to an electric heater 10 arranged to heat the lower part of the main body of the gas pressure regulator 2, and as the liquefied gas is vaporized by the heater 10, the gas It is designed to prevent the lower part of the main body of the pressure regulator 2 from freezing.

Here, the above-mentioned gas flow meter 4 not only has the function of displaying the instantaneous flow rate of gas, but also has the function of measuring the cumulative flow rate to measure how much gas has been used after the gas has been used. .

In order to provide the display and sensing functions as described above, the illustrated example is provided with the following electrical configuration.

That is, the gas flow meter 4 is equipped with a connected instantaneous and cumulative flow rate measuring electric circuit section I that is equipped with a float height detection oscillator H shown in FIG. What is shown as part H is gas g such as CO ₂ from the gas inlet 5.
When the gas g flows into the tapered tube 11' through the meter introduction path 11, a magnetic float 12 with magnetic permeability made of ferrite or the like floats in proportion to the instantaneous flow rate of the gas g, and the gas g flows into the tapered tube 11'. 11' from the gas outlet 13, 13... to the outer cylinder 1
After passing through a meter outlet path 16 through a gap path 15 formed by 4, the gas flows to the gas outlet 7.

Further, a solenoid coil 17 is wound around the outer periphery of the tapered tube 11' near the magnetic float 12, and the coil 17 is connected to a variable oscillator 18, so that the magnetic float 12 floats as described above. Therefore, by utilizing the fact that the inductance of the solenoid coil 17 changes,
The inductance variable detected by the float height detector 19 consisting of the magnetic float 12 and the solenoid coil 17 is oscillated by replacing it with a frequency variable by the oscillator 18, and the float height is determined by measuring this oscillation frequency. In other words, the instantaneous flow rate of gas is displayed.

Further, as described above, the float height detector 19, the oscillator 18, the power source 20 by the welding power source device D, etc.
By adding electrical members as shown in FIG. 5 to the float height detection oscillation section H, which is configured by
is configured.

That is, a fixed oscillator 21 that oscillates an output wave of a predetermined frequency is connected to the output side of the oscillator 18, and an input side of a phase detection circuit 22 is connected to the output side of the detection circuit 22. An instantaneous value counter 24 is connected via a frequency divider 23.

Further, an integration counter 26 is connected to the output side of the counter 24 via an integration frequency divider 25, and the output sides of the instantaneous value counter 24 and the integration counter 26 are connected to each other by a changeover switch 27.
It is connected to a display 28 such as a digital display so as to be switchable.

Therefore, if the changeover switch 27 is now switched to the position shown in the figure, the output of the instantaneous value counter 24 will be introduced to the display 28, but if the main switch 29 is turned ON, the circuit shown in FIG. 5 will be activated. Then, the oscillator 18 of the float height detection oscillator H has a frequency proportional to the instantaneous flow rate of the gas (for example, 130.160KHz to 146.000KHz) as described above.
The output is oscillated.

Then, the oscillation wave and the predetermined frequency output wave (for example, 130KHz) from the fixed oscillator 21 are introduced into the phase detection circuit 22, so that the frequency difference value output between the two waves is output from the same circuit 22 for instantaneous value. The signal is applied to the frequency divider 23 (for example, a 1/32 frequency divider), and its output is input to the instantaneous value counter 24 at the next stage, where an input count proportional to the instantaneous flow rate of the gas is performed. The information is displayed as a digital display on the display 28 as described above.

Next, when the changeover switch 27 is moved down from the illustrated position, the output of the integration counter 26 will be applied to the display 28, and the output of the instantaneous value counter 24 obtained as described above will be applied to the display 28. , is further introduced to the integration counter 26 via the integration frequency divider 25 (for example, a 1/1024 frequency divider), and thus an output proportional to the total amount of gas used is applied from the counter 26 to the display 28. The integrated flow rate of the gas can be read.

Furthermore, in FIG. 4, numeral 30 indicates an alarm unit, and the display 28 displays the integration counter 2 as described above.
When the input value applied from 6 reaches a predetermined value, the alarm 30' of the section 30 sounds or lights up. Therefore, the alarm time may be determined based on the cumulative flow rate value of an appropriately selected gas, or the remaining amount of the gas in the cylinder.

《Effect of the invention》 Since the present invention is constructed as described above, it is possible to know not only the instantaneous flow rate of gas but also the cumulative flow rate of gas. then 1500
It is possible to predict with higher reliability than conventional methods that the cylinder is about to run out of gas by issuing an alarm when the cumulative flow rate reaches 500 or when the remaining amount in the gas cylinder reaches 500. Therefore, since the liquefied gas cylinder can be prepared or replaced at the appropriate time, welding work can be performed without causing uneven welding, and the operator can work with peace of mind.

[Brief explanation of the drawing]

Figure 1 is an overall explanatory diagram showing a conventional pressure regulator for liquefied gas cylinders used for welding, Figure 2 is a chart showing changes in the internal pressure of the liquefied gas cylinder with respect to the amount of gas used, and Figure 3 is the pressure adjustment device according to the present invention. A front explanatory view showing how the adjustment device is used, Figure 4 is the third
FIG. 5 is a longitudinal sectional front view of the float height detection oscillator installed in the gas flow meter shown in FIG. 1...Liquefied gas cylinder, 1'...Main cock, 2...
Gas pressure regulator, 4...Gas flow meter, 5...Gas inlet, 6...Gas flow rate adjustment valve, 7...Gas outlet, 8...Secondary side pressure gauge, 9...Pressure adjustment knob,
12... Magnetic float, 17... Solenoid coil, 18... Oscillator, 21... Fixed oscillator, 22
... Phase detection circuit, 23 ... Instantaneous value frequency divider, 2
4... Instantaneous value counter, 25... Integration divider, 26... Integration counter, 27... Changeover switch, 28... Display, 30... Alarm, 3
0'... Alarm, H... Oscillator for detecting float height,
I... Instantaneous and integrated flow rate measurement electrical circuit section.

Claims (1)

[Scope of Claim for Utility Model Registration] (1) The primary side of a gas pressure regulator having a pressure adjustment knob and a secondary side pressure gauge is connected to the main valve of the liquefied gas cylinder, and the secondary side of the regulator is connected to the main valve of the liquefied gas cylinder. The gas inlet of a gas flow meter having a gas outlet is connected via a flow rate adjustment valve, and the gas flow meter is equipped with an indicator that shows the instantaneous gas flow rate and the cumulative gas flow rate or the remaining amount of gas in the cylinder. A liquefied gas cylinder which is equipped with an electric circuit unit for measuring the instantaneous and cumulative flow rate of the gas, and is connected to an alarm unit that is activated when the cumulative flow rate of the gas concerned or the remaining amount of gas in the cylinder reaches a set value. pressure regulator. (2) In the electric circuit for measuring instantaneous and cumulative flow rates, a magnetic float installed in the gas flow path of the gas flow meter floats in response to the flow rate of the gas, thereby applying a variable inductance to the solenoid coil of the oscillator. The float height detection oscillator is configured to cause the oscillator to oscillate as a frequency variable corresponding to the variable, and the oscillator of the oscillator has a predetermined frequency output wave of a fixed oscillator on its output side. At the same time, a phase detection circuit is connected, and the frequency difference output of the two oscillators obtained by this phase detection circuit is connected to an instantaneous value counter via an instantaneous value frequency divider, and the output side of the counter is is connected to an integration counter via an integration frequency divider, and the output sides of the instantaneous value counter and the integration counter are connected to a display in a switchable manner. Pressure adjustment device for liquefied gas cylinders.